Potential for Greenhouse Gas Emission Reductions by Using Biomethane as a Road Transportation Fuel
Uusitalo, Ville (2014-11-28)
Väitöskirja
Uusitalo, Ville
28.11.2014
Lappeenranta University of Technology
Acta Universitatis Lappeenrantaensis
Julkaisun pysyvä osoite on
https://urn.fi/URN:ISBN:978-952-265-663-6
https://urn.fi/URN:ISBN:978-952-265-663-6
Tiivistelmä
The aim of this thesis is to study whether the use of biomethane as a transportation fuel
is reasonable from climate change perspective. In order to identify potentials and
challenges for the reduction of greenhouse gas (GHG) emissions, this dissertation
focuses on GHG emission comparisons, on feasibility studies and on the effects of
various calculation methodologies. The GHG emissions calculations are carried out by
using life cycle assessment (LCA) methodologies. The aim of these LCA studies is to
figure out the key parameters affecting the GHG emission saving potential of
biomethane production and use and to give recommendations related to methodological
choices. The feasibility studies are also carried out from the life cycle perspective by
dividing the biomethane production chain for various operators along the life cycle of
biomethane in order to recognize economic bottlenecks.
Biomethane use in the transportation sector leads to GHG emission reductions
compared to fossil transportation fuels in most cases. In addition, electricity and heat
production from landfill gas, biogas or biomethane leads to GHG reductions as well.
Electricity production for electric vehicles is also a potential route to direct biogas or
biomethane energy to transportation sector. However, various factors along the life
cycle of biomethane affect the GHG reduction potentials. Furthermore, the
methodological selections have significant effects on the results. From economic
perspective, there are factors related to different operators along the life cycle of
biomethane, which are not encouraging biomethane use in the transportation sector.
To minimize the greenhouse gas emissions from the life cycle of biomethane, waste
feedstock should be preferred. In addition, energy consumption, methane leakages,
digestate utilization and the current use of feedstock or biogas are also key factors. To
increase the use of biomethane in the transportation sector, political steering is needed
to improve the feasibility for the operators. From methodological perspective, it is
important to recognize the aim of the life cycle assessment study. The life cycle
assessment studies can be divided into two categories: 1.) To produce average GHG
information of biomethane to evaluate the acceptability of biomethane use compared to
fossil transportation fuels. 2.) To produce GHG information of biomethane related to
actual decision-making situations. This helps to figure out the actual GHG emission
changes in cases when feedstock, biogas or biomethane are already in other use. For
example directing biogas from electricity production to transportation use does not
necessarily lead to additional GHG emission reductions. The use of biomethane seems to have a lot of potential for the reduction of greenhouse gas emissions as a
transportation fuel. However, there are various aspects related to production processes,
to the current use of feedstock or biogas and to the feasibility that have to be taken into
account.
is reasonable from climate change perspective. In order to identify potentials and
challenges for the reduction of greenhouse gas (GHG) emissions, this dissertation
focuses on GHG emission comparisons, on feasibility studies and on the effects of
various calculation methodologies. The GHG emissions calculations are carried out by
using life cycle assessment (LCA) methodologies. The aim of these LCA studies is to
figure out the key parameters affecting the GHG emission saving potential of
biomethane production and use and to give recommendations related to methodological
choices. The feasibility studies are also carried out from the life cycle perspective by
dividing the biomethane production chain for various operators along the life cycle of
biomethane in order to recognize economic bottlenecks.
Biomethane use in the transportation sector leads to GHG emission reductions
compared to fossil transportation fuels in most cases. In addition, electricity and heat
production from landfill gas, biogas or biomethane leads to GHG reductions as well.
Electricity production for electric vehicles is also a potential route to direct biogas or
biomethane energy to transportation sector. However, various factors along the life
cycle of biomethane affect the GHG reduction potentials. Furthermore, the
methodological selections have significant effects on the results. From economic
perspective, there are factors related to different operators along the life cycle of
biomethane, which are not encouraging biomethane use in the transportation sector.
To minimize the greenhouse gas emissions from the life cycle of biomethane, waste
feedstock should be preferred. In addition, energy consumption, methane leakages,
digestate utilization and the current use of feedstock or biogas are also key factors. To
increase the use of biomethane in the transportation sector, political steering is needed
to improve the feasibility for the operators. From methodological perspective, it is
important to recognize the aim of the life cycle assessment study. The life cycle
assessment studies can be divided into two categories: 1.) To produce average GHG
information of biomethane to evaluate the acceptability of biomethane use compared to
fossil transportation fuels. 2.) To produce GHG information of biomethane related to
actual decision-making situations. This helps to figure out the actual GHG emission
changes in cases when feedstock, biogas or biomethane are already in other use. For
example directing biogas from electricity production to transportation use does not
necessarily lead to additional GHG emission reductions. The use of biomethane seems to have a lot of potential for the reduction of greenhouse gas emissions as a
transportation fuel. However, there are various aspects related to production processes,
to the current use of feedstock or biogas and to the feasibility that have to be taken into
account.
Kokoelmat
- Väitöskirjat [1099]